Spect examination device

ABSTRACT

The invention relates to a tomography device and method, particularly for single photon emission computed tomography (SPECT). The device for carrying out a tomography method, especially for carrying out a single photon tomography, comprises a multi-pinhole collimator and a detector for detecting gamma quanta or photons that penetrate the multi pinhole collimator. According to the device for carrying out the tomographic method, the distance between the object and the multi-pinhole collimator is selected to be smaller than the distance between the multi-pinhole collimator and the surface of the detector. The invention provides a device and a method with which the desired result can be achieved with a high spatial resolution and sensitivity.

[0001] The invention discloses a device and a method for tomography, especially single photon emission computed tomography (SPECT).

[0002] Single photon emission computed tomography is a method with associated devices for three-dimensional imaging of radio pharmaceuticals, which have been introduced into an object. Human beings or animals may be provided as the object. The radio pharmaceuticals introduced into the object emit photons or gamma quanta. These photons are registered and evaluated by the device. The position, that is to say, the spatial distribution of the radio pharmaceuticals, is obtained as the result of this evaluation. In turn, the position of the radio pharmaceuticals allows inferences to be made regarding the object, for example, regarding a distribution of tissue in the object.

[0003] One known device for the implementation of single photon emission computed tomography comprises a gamma camera and a collimator positioned in front of the camera. The collimator is generally a lead plate with a large number of channels passing in a perpendicular direction through the plate. The provision of these channels ensures that, on the one hand, only photons passing in a perpendicular direction are registered and, on the other hand, that a spatially resolved measurement is possible. The camera together with the collimator is moved around the object. As a result, a large quantity of positional data is gathered. These data are known as projection shots. The position of the radio pharmaceuticals within the object can be determined from the positional data obtained from around the object.

[0004] In order to screen scattered radiation originating from the photons, it is generally also necessary to gather energy data. The camera is therefore normally designed in such a manner that the energy of the falling photons can be determined at the same time.

[0005] Scattered radiation always provides a lower energy by comparison with the actual measured radiation. Accordingly, scattered radiation can be screened ignoring photons with low energy. Determining an upper limit for the energy of the photons may also be relevant for screening background radiation.

[0006] The methods and/or the devices described above already represent part of the general available technical knowledge, because methods and devices of this kind have been used for more than 30 years.

[0007] Single photon emission computed tomography (SPECT) and position emission tomography (PET) are instruments for the quantitative imaging of spatial radio tracer distributions in vivo. Alongside their use in human medicine, these methods can be used in pharmacological and pre-clinical research for the development and evaluation of innovative tracer compounds. Although various systems for the examination of small laboratory animals are already available in the context of PET, corresponding developments have not been made in the field of SPECT or have only been made to an inadequate extent; indeed, this is still the case although TC-99m and I-123-marked radio pharmaceuticals have a disproportionately greater relevance than PET nuclides.

[0008] A high-resolution, high-sensitivity animal SPECT would provide the advantage for pre-clinical research of an animal-preserving method, which would allow dynamic and reproducible studies of an individual to be performed with reliably informative results. This advantage is favoured by the fact that, with the above named radio isotopes, extremely high specific activities can be achieved (a factor of approximately 100 by comparison with PET nuclides), which are indispensable for interference-free in vivo measurements (low mass dose). In this context, corresponding marking methods must still be developed.

[0009] To improve the positional resolution by comparison with the prior art named above, a pinhole collimator is used in single photon emission computed tomography. A pinhole collimator is characterised by a single pinhole, through which the photons pass. If the object is closer to the pinhole collimator than the surface of a gamma camera and/or of a detector, this will ultimately achieve an enlarged positional resolution. The photons do not pass through the pinhole collimator exclusively in an perpendicular direction. Instead, they enter and leave in a conical shape. Since the cone located behind the pinhole collimator is larger than the cone in front of the pinhole collimator, an improvement in positional resolution is achieved by comparison with the prior art named in the introduction.

[0010] In order to obtain a good positional resolution with a pinhole collimator, the aperture and/or pinhole, through which the photons pass, should be small. However, the smaller a pinhole is, the fewer the photons which will pass through this pinhole. Accordingly, as the pinholes become smaller, the sensitivity of the device declines in a disadvantageous manner. In this context, sensitivity is defined as the ratio of the measured counting rate to the activity present in the object.

[0011] If the sensitivity is too low, single photon emission computed tomography is ultimately no longer possible.

[0012] The object of the invention is to create a device with an associated method of the type named above, which allows high-resolution and high-sensitivity measurements.

[0013] The object of the invention is achieved by a device with the features of claim 1 and a method with the features of the co-ordinated claim. Advantageous embodiments are defined in the dependent claims.

[0014] The device claimed comprises a multiple-pinhole collimator together with a detector for registering photons which pass through the multiple-pinhole collimator. Accordingly, the collimator provides a large number of pinholes. In one embodiment of the invention, the detector is designed in such a manner that it can also measure the energy of the photons detected.

[0015] Since the collimator provides several pinholes, the sensitivity of the device is increased accordingly. The use of a pinhole collimator, by comparison with the use of collimators which can only register perpendicular beams falling in a perpendicular direction, provides the advantage of a high positional resolution. Accordingly, a device with good positional resolution and good sensitivity is provided.

[0016] During the operation of the device, the object is closer to the multiple-pinhole collimator than the camera and/or detector surface, in order to achieve a good positional resolution. Within the device, the holder for the object (patient stretcher) is therefore closer to the multiple-pinhole collimator than the camera and/or detector.

[0017] The distances between the individual apertures or pinholes in the multiple-pinhole collimator are preferably selected in such a manner that the cones striking the camera sometimes overlap. It is advantageous to allow overlapping regions in order to achieve a good positional resolution and good sensitivity. In one embodiment of the invention, these overlapping regions represent no more than 30%, preferably up to 70% of the total area of a cone, which is formed by the photons passing through a pinhole in the multiple-pinhole collimator.

[0018] In conventional pinhole tomography (pinhole tomography), the centre of the pinhole is located on the midline perpendicular of the detector. Furthermore, the axis of the pinhole, that is, the axis of symmetry of the pinhole in the collimator is perpendicular to the detector. In this context, a reconstruction method is used, wherein it is assumed that the photon which strikes the camera from the centre of the object forms a right angle with the camera surface. The base area of the cone which is formed on the camera will then always be circular.

[0019] When using a multiple-pinhole collimator, this situation is frequently not the case. Accordingly, in one embodiment of the invention, a reconstruction method is provided, which takes such deviating conditions into account. If a photon originating from the centre of the object no longer strikes the surface of the camera and/or the detector in a perpendicular direction, then a circular cone (idealised condition) will not be formed on the surface of the camera. Instead, the cone on the camera will always take the form of an ellipse. According to the invention, this problem is resolved by using an iterative reconstruction method. The starting point of the iterative reconstruction method is an assumed distribution within the object and indeed generally a spatial distribution. A calculation is then performed to determine which mass results would achieve the assumed distribution. The calculated result is then compared with the actually measured results. Following this, a new, modified distribution is assumed. Once again, the result formed on the camera for this new distribution is calculated and compared. The calculations investigate whether the new distribution corresponds more closely to the measured result. In this manner, after an adequate number of steps have been implemented, a distribution is determined wherein the calculated results agree adequately well with the actual results (measured results). In particular, the iterative reconstruction method is concluded, when the calculated results agree with the measured result with a specified accuracy. The iteration method therefore comprises a so-called forward projection, that is to say, the calculation of the results for an assumed distribution.

[0020] The iterative method also provides the advantage that overlapping areas of the cones formed on the surface of the camera and/or detector can be compared with the actual result. For this reason, the method is preferable to other reconstruction methods. It is therefore also possible to allow overlapping regions thereby achieving a good positional resolution.

[0021] In a further embodiment of the invention, the multiple-pinhole collimator provides a plate, which is manufactured from tungsten and iridium. These materials provide a better attenuation coefficient relative to photons by comparison with lead. Iridium is the more suitable of the named materials for the attenuation of photons. However, iridium is extremely expensive. Accordingly, for reasons of cost, tungsten is used in those positions in which the requirements for attenuation performance are lower. Those parts of the plate in which the requirements for the attenuation of photons are particularly high are manufactured from iridium. In particular, this relates to the regions of the plate which are adjacent to the pinholes.

[0022] A pinhole in the plate advantageously opens from both sides into the plate in the form of a funnel. The requirement for attenuation is particularly high at this position, especially regarding the walls of the pinhole. Accordingly, the funnel walls are preferably manufactured from iridium. In this context, the plate is typically 3 to 10 mm thick.

[0023] Photons which originate from the interior of the object are generally attenuated in dependence upon the tissue. In order to take this attenuation into account in the evaluation according to the prior art, a homogeneous attenuation coefficient is assumed, which corresponds to the attenuation coefficient of water. The attenuation is, however, additionally dependent upon the contour of the object. In one embodiment of the invention, the outer contour of the object is determined within the framework of the evaluation, and the attenuation is calculated in dependence upon the contour. Further-improved results are obtainable in this manner.

[0024] The measure for the outer contour of the object is the Compton scattered radiation. In one embodiment of the invention, the Compton scattered radiation is measured, for example, in a so-called Compton window. The Compton scattered radiation is taken into account within the reconstruction method, and the contour of the object is determined from this.

[0025] When a photon strikes the camera and/or the detector, the position of incidence is measured with an inaccuracy typical of the camera or the detector. In a further embodiment of the method, within the context of a forward projection, upon which the iterative reconstruction method is based, the imaging property, that is to say the inaccuracy typical of the camera or the detector, is taken into account in the evaluation. Once again, taking the inaccuracy of measurement into account by means of an iterative method of the type named above is both successful and reliable.

[0026] If a radiation source disposed within the object is located at a distance relatively remote from the multiple-pinhole collimator (that is to say, in a region of the object, which is particularly remote from the collimator), then the sensitivity will decline. One embodiment of the reconstruction method, takes this reduction of sensitivity into account in the forward projection.

[0027] The imaging performance of the camera and/or the detector also depends upon the distance between the radiation source and the multiple-pinhole collimator. This imaging performance changing in dependence upon distance is also taken into account iteratively in one embodiment of the method.

[0028] Relevant program segments for an iteration method, which is capable of working through the steps of the invention described above, are indicated below. The programs consist of the input parameters listed below. Typical values for input parameters of this kind are also indicated. The term “hole” is used synonymously with the term “pinhole” (of the multiple-pinhole collimator).

[0029] Regarding the calculation of the contour and/or the outline of the object, one embodiment performs the calculation of the object contour in an “zeroed” iteration. This makes use of a property of Compton scattering which actually degrades the image quality: namely photons detected with a wrong direction.

[0030] Photons detected a wrong direction represent a background in the projections, which disadvantageously impairs the image quality. However, they can also be of benefit. In practically all clinical cases, they cause the entire extension of the patient to appear in the projections. Even if a tracer, that is to say, a radio pharmaceutical, is deposited very specifically in a narrowly circumscribed organ, photons seem to originate from all other regions of the patient used for imaging. In fact, these are photons, which have their origin in the narrowly circumscribed organ, but, as a result of Compton scattering, they appear to “illuminate” the entire patient. This circumstance is exploited in order to calculate the contour of the object.

[0031] The calculation takes place in several stages:

[0032] 1) Production of “binary” projections. These represent a simplification of the actual projection, because any pixel content greater than 0 is set to 1.

[0033] The essential characteristic in this context is a user-controlled threshold setting, which on the basis of conclusiveness, separates the projection of the actual object of examination, the patient, from the background. Calculation of this threshold is based on an averaged maximum derived from all projections.

[0034] 2) Back projection of the binary projections into the object space

[0035] 3) On the basis of the “multiplicity” of voxels (small, generally cubic element of volume), that is, the frequency, with which a voxel is observed under the relevant collimator geometry over all angles of the projections, a threshold (determined heuristically for the relevant geometry) establishes which voxels belong in the very first approximation to the interior space of the body. (The limitation of the interior space of the body is the body contour.)

[0036] 4) Multiple folding with 3d-folding core

[0037] 5) Repetition of point 3

[0038] 6) Double run-through of

[0039] a) 3d-folding

[0040] b) Inclusion of the voxels, into which something has been folded, in the interior space of the body.

[0041] The basic structure of the device is illustrated with reference to the diagram.

[0042] An object 1 is located closer to a multiple-pinhole collimator than the detector surface 2. The multiple-pinhole collimator 3 provides pinholes 4, which open in the shape of a funnel from both sides into the collimator 3, thereby allowing obliquely falling photons to pass through the pinholes. The tips 5 of the multiple-pinhole collimator 3 are made of iridium. The other regions of the multiple-pinhole collimator are made from tungsten. Photons 6 pass from the object 1 through the pinholes and onto the surface of the detector 2. The object 1 is therefore reproduced on the surface of the detector 2 in enlargement. Overlapping regions 7 are provided between the individual cones, formed by the photons.

[0043] In the diagram, the pinholes 4 are at a uniform distance from one another. In one embodiment of the invention, these distances are non-uniform. 

1-7. (cancelled).
 8. A device for the implementation of a tomographical method using single photon emission computed tomography comprising a multiple-pinhole collimator and a detector having a surface for registering photons or gamma quanta which pass through the multiple-pinhole collimator.
 9. A device according to claim 8, wherein the distance between a holder for an object to be imaged and the multiple-pinhole collimator is smaller than the distance between the multiple-pinhole collimator and the surface of the detector.
 10. A device according to claim 8, wherein the multiple-pinhole collimator is made from at least one metal selected from the group consisting of tungsten and iridium.
 11. A device according to claim 8, wherein the multiple-pinhole collimator includes pinholes and regions formed of iridium adjacent to the pinholes.
 12. A device according to claim 8, wherein the multiple-pinhole collimator includes pinholes and the pinholes open in a funnel shape into the multiple-pinhole collimator.
 13. A device according to claim 8, wherein the multiple-pinhole collimator is made from at least one metal selected from the group consisting of tungsten and iridium, the multiple-pinhole collimator includes pinholes and regions formed of iridium adjacent to the pinholes, and the pinholes open in a funnel shape into the multiple-pinhole collimator.
 14. A device according to claim 9, wherein the multiple-pinhole collimator is made from at least one metal selected from the group consisting of tungsten and iridium, the multiple-pinhole collimator includes pinholes and regions formed of iridium adjacent to the pinholes, and the pinholes open in a funnel shape into the multiple-pinhole collimator.
 15. A device according to claim 9, wherein the multiple-pinhole collimator includes pinholes, the distances between adjacent pinholes, the size of the pinholes and the position of the holder are arranged so that cones formed by photons or gamma quanta on the surface of the detector partially overlap.
 16. A tomographical method using single photon emission computed tomography comprising providing a multiple-pinhole collimator and a detector having a surface for registering photons or gamma quanta which pass through the multiple-pinhole collimator, spacing an object to be imaged and the collimator a first distance which is smaller than a second distance between the multiple-pinhole collimator and the surface of the detector.
 17. A method as in claim 16, wherein the multiple-pinhole collimator is made from at least one metal selected from the group consisting of tungsten and iridium.
 18. A method as in claim 16, wherein the multiple-pinhole collimator includes pinholes and regions formed of iridium adjacent to the pinholes.
 19. A method as in claim 16, wherein the multiple-pinhole collimator includes pinholes and regions formed of iridium adjacent to the pinholes.
 20. A method as in claim 16, wherein the multiple-pinhole collimator includes pinholes and the pinholes open in a funnel shape into the multiple-pinhole collimator.
 21. A method as in claim 16, wherein the multiple-pinhole collimator is made from at least one metal selected from the group consisting of tungsten and iridium, the multiple-pinhole collimator includes pinholes and regions formed of iridium adjacent to the pinholes, and the pinholes open in a funnel shape into the multiple-pinhole collimator.
 22. A method as in claim 21, wherein the multiple-pinhole collimator includes pinholes, the distances between adjacent pinholes, the size of the pinholes and the position of the object are selected so that cones formed by photons or gamma quanta on the surface of the detector to partially overlap.
 23. A method as in claim 21, wherein the overlap is up to 35% of the area of the cones formed on the surface of the detector.
 24. A method as in claim 16, wherein the multiple-pinhole collimator is made from at least one metal selected from the group consisting of tungsten and iridium, the multiple-pinhole collimator includes regions formed of iridium adjacent to the pinholes, and the pinholes open in a funnel shape into the multiple-pinhole collimator.
 25. A method as in claim 24, further including a reconstruction method to determine an object image including assuming different distributions of radio pharmaceuticals in the object, calculating the measured results which would achieve the assumed distributions, and selecting as a result of the reconstruction the assumed distribution for which the calculated measured result most accurately agrees with the measured result obtained.
 26. A method as in claim 24, wherein the multiple-pinhole collimator includes pinholes, the distances between adjacent pinholes, the size of the pinholes and the position of the object are selected so that cones formed by photons or gamma quanta on the surface of the detector partially overlap.
 27. A method as in claim 24, wherein the overlap is up to 35% of the area of the cones formed on the surface of the detector. 